Cam actuated switch



May 11, 1948. F. P. METZGER 2,441,434

CAM ACTUATED SWITCH Filed June 13, 1944 3 Sheets-Sheet 1 Fed/220k Mafz qer IN VEN TOR B Y m a A TTORNE Y May 11, 1948. F. P. METZGER 34 CAM ACTUATED SWITCH Filed June 13, 1944 3 Sheets -Sheet 2 INVENTOR BY W ATTORNEY May 11, 1948. F. P. METZGER CAM ACTUATED SWITCH Filed June 15, 1944 s Shee'fos-Sheet 5- MM Wm W w Msfz 475/" firs 09-105 IN VEN TOR A TTORNE Y Patented May 11, 1948 UNITED STATES PATENT oFFIcE CAM Meiji? swnien Worthington-Gamon Meter Company, Newark, N. J a corporation of New Jersey Application June 13, 1944, Serial No. 540,119 1 Claim. (01. zoo-27) This invention relates to the control of individual electric circuits in a multi-circuit system employed in water treating and purifying systems, and more particularly to a meter actuated switch means for opening and closing the individual circuits at predetermined time intervals for controlling auxiliary devices in accordancewith the rate of flow of liquid through the meter.

In water treating or precipitating systems wherein chemicals are added to the water fortreating purposes; it is common practice to add the chemical to the water intermittently. The raw of untreated water is metered, and a predetermined quantity of chemical is fed to the raw water at intervals based on the passage of a predetermined quantity of raw water through the meter. Electrically actuated devices are employed for controlling the feed of chemical to the raw water, and uniform treatment of the water requires that the chemical liquid be added in volumetric proportion'to the raw water.

In the treating process, precipitate or sludge settles in" the .bottom of the treating tank, the latter usually having a conical bottom It is common. practice to remove the sludge that settles in. the bottom of the tank through the medium of a large area quick-openingvalve at long. in.-, tervals of accumulatiomorthrough the medium of .an electrically operated proportionalv sludge removing valve. objectionable because of its. disturbance of the softening process and of the supply of treated water, while the second method is eflicient to a degree that practically eliminates the necessity for opening the, large blow-off valve. ,The quantityof sludge settling in the bottom of the tank depends upon the amount ofimpurities in the water bein itreated, and in water of approximately constant impurity content, the quantity of sludge is essentially in proportion to the quantity of water treated. It is desirable therefore thatthe proportionalsludge removing valves be. so controlledas to provide for frequent small quantity blow-off in proportion to the amount of, raw water delivered to the treating apparatus, Efilcient treatment of water requires that operations of the foregoing The first method of removal is nature bb effectively correlated with respect to the rate'of flow ofrawwater. Accordingly, an object ofthe present invention is toprovide a meter actuated; switch means for controlling individual,

operating circuits in a multi-circuit system to the end that,v the operations maybe performed in a correlated and eflicient manner based on the quantity of raw water fi'owingthrough the meter. Another object is toprovide in a water meter,

a novel switch means for controlling individual circuits in a correlated manner based, on the flow of water through the meter, and in which the switch means are designed to constitute a unit of simple construction which may easily be incorporated in a conventional meter- A further object is toprovide a switchmeans for controlling. individualcircuits in .a multi-circuit. system, and inwhich the switch means are of such constructionasto facilitate incorporation of the switch meansbetween the gear train and the" register of. a standard meter, with the switch means constituting a driving connection between the geartrain and the register- A further object isto provide in awater meter, a switchlmeans. embodying a plurality of switch units which may be. incorporated in the meter tobe controlled thereby. in accordance with the quantityof water flowing through the, metenand in which novelgear. train and cam means ar incorporated, for operating the respective switch units at predetermined intervals,

With these and other objects in view, as may appear fromthe accompanying specification, the invention consists of various features of construction and combination-pf parts, which will be first described in connection with the accompanying drawings, showing a .proportioning .meter of a preferred form embodying the invention, and the features forming the invention will be specifically pointed out in the claim.

In the drawings: m V

Figure 1 illustrates an elevationalview, partly in section, of a water treating or purifying system embodyingthepresent invention. v

Figure 2 is a partial sectional view of a proportioning meter showing the switch means incorporated therein. I r g Figure 3 is atop plan view of the switch means, with the containing case thereof shown in section.

; Figure 415 a side view of the structure shown in Figure 3, with the containing case shown in section.

Figure 5, is a dissemin te view of the electri top of which raw or untreated water is delivered by means of an inlet pipe '2. A suitable chemical reagent is introduced into the tank I through an inlet pipe 3, the quantity of chemical reagent being controlled by a mixing tank and proportioning apparatus indicated generally at 4. This apparatus includes a decanting tube 5 mounted inside the tank of the apparatus and pivotally supported by a swivel joint 6 at its discharge end. The inlet end I of the decanting tube 5 is so located that it will skim the reagent from the top of the body of reagent in the tank. The dispensing of the reagent from the tank 4 is controlled by lowering the decanting tube 5, the dispensed reagent being deposited in a chemical dilution box 8 having communication with a pump 9 for pumping the reagent through the pipe 3.

To the decanting tube 5 is connected a line or cable which is operated by a motor l2. The motor [2 operates in a direction for rotating the drum H to unwind the line l8 and lower the decanting tube a predetermined distance, but the line is rewound on the drum manually by a crank IS. The tank I is provided with a quick opening sludge valve 4 and an automatic proportional sludge removing valve |'5, both of which are located at the bottom of the treating tank, and the latter of which is electrically operated. A proportioning meter 16 is interposed in the raw water inlet pipe 2 for measuring the quantity of raw water flowing to the treating tank I. The structure so far described is old, the present invention being concerned with an electric circuit and switch means for controlling the motor l2 and the valve l5 in accordance with the quantity of raw water flowing through the meter l6.

In Figure 2, the proportioning meter l6 includes a spindle I! which is driven by a gear |8, the latter comprising one gear of the usual gear train (not shown) with which such meters are provided. To the upper end of the spindle I1 is attached a speed change gear |9 having mesh with a speed change gear 20 attached to a spindle 2| of a switch means 22 interposed between the gear train of the meter I6 and its register 23, the latter being of conventional construction.

Figures 3, 4, and 6 illustrate the construction of th switch means '22. The switch means 22 include a casing part 24 and a bottom plate or base 26 adjacent which is located the speed change gear 20, and through which the spindle 2| projects. A generally U-shaped bracket 21 is formed integrally with the base 26, the spindle 2| being journaled in both the base and the wall portion 28 of the bracket 21. A pinion 29 is keyed to the shaft 2 I and meshes with a gear 30 keyed to a spindle 3| also journaled in both the base 26 and the wall 28. The spindle 3| extends some distance upwardly from the wall 28 and has a speed change gear 32 fixed thereto. This speed change gear meshes with a speed change gear 33 (see Figure 2) attached to a drive spindle 34 of the register 23. Thus the gear train of the meter I6 is drivingly connected with the register 23 through the gear I8, spindle I1, gears l9 and 28, spindle 2|, gears 29 and 39, spindle 3|, and gears 32 and 33.

The base 26 serves as a mount for two switch units 35 and 36, both of which are operatively incorporated in the switch means '22 and control the operating circuits for the proportional sludge removing valve I5 and the motor |2, respectively. The switch units 35 and 36 are of the same construction, the units being preferably of the type shown in Patent No. 1,960,020, issued May 22,

1934. Figure 6 illustrates the general construction of the unit 35, which unit comprises a hollow insulating body 31 and an insulating cover 38 sealed thereto. Within the housing structure of the unit 35 is mounted a resilient contact element 39 in the nature of a leaf spring. One end of the contact element is made secure to the body 31 by a screw 49 threaded into a conductor sleeve 4| to which a terminal clip 42 is electrically connected, this clip being in turn attached to a circuit wire 43.

Bowed and tensioned arms 44 are formed integrally with the contact element 39 and have end abutment with a spaced body 45. To the free end of the contact element 39 is attached a contact head 46 which lies between two contact stops 41 and 48. The contact stop 48 is electrically connected with a sleeve 49 into which a terminal screw 50 is threaded to anchor a terminal clip 5| electrically connected with a circuit or line wire 52.

The contact element 39 is normally positioned in the manner of Figure 6, at which time the contact head 46 lies in engagement with the stop 41, The circuit wires 43 and 52 may be electrically connected by moving the contact element 39 downwardly to bring the head 46 into engagement with the stop 48. The contact element 39 and its spring arms 44 are so devised as to move the contact element with a snap action to either its normal or circuit closing position. A slight downward movement of the contact element from the position of Figure 6 causes the element to snap into engagement with the contact 48, while a release of pressure from the contact element permits the latter to snap back to its normal position. Means for depressing the contact arm comprises a pin 53 which slides freely in a bore 54 in the cover 38. One end of the in extends sufiiciently far beyond the cover 38 to be engaged by a flexible actuating arm 55 which has one end fixed to the cover 38 by a screw 56. To the free end of the arm 55 is connected a U-shaped bracket 51 in which is mounted a roller 58. Since the units 35 and 36 are identical, similar but primed reference characters are applied to the corresponding parts of the unit 36.

I Means for flexing the arms 55 and 55 to close the switch units 35 and 36, respectively, comprise cams 59 and 68. The cam 68 is attached to a spindle 6| journaled in the base 26 and the wall 28, the spindle being rotated by a gear 62 fixed to this spindle and meshing with a gear 63 keyed to the spindle 2|. The cam 60 moves the arm 55' sufficiently far to depress the pin 53' to close the switch unit 36, the switch unit being closed once for each rotation of the spindle 6|.

The cam 59 is fixed to a spindle 64 rotatably journaled in the base 26 and the wall 28. To the spindle 64 is attached a large gear 65 which meshes with a pinion 66 keyed 'to a spindle 61, the latter being journaled in the base 26 and the wall 28. Upon the spindle 61 is attached a gear 68 which is rotated intermittently one tooth at a time through the medium of a one tooth pinion 69 attached to the shaft 2|. It will thus be seen that the switch units 35 and 36 are closed at differcnt intervals, since the cams 59 and 60 rotate at different but predetermined speeds in proportion to the rate of flow of liquid through the meter I6. The intervals between the respective switch closing operations are dependent upon the quantity measured by the meter l6 and can be regulated by the rate of flow. In addition, speed change gears of ratios diiiering from the gears l9 and: 20 may be employed. The frequency of the time intervals will, of course, depend upon local operating conditions, as. well as uponthe specific work to be performed by; the individual operating. circuits controlled by. the switch. units, since itis obvious that'local conditions-will vary and thatthe switch units may control individual operating circuits performing work other. than that shownand described.

Figure 5" illustrates the electric circuit system as a whole. The terminal clips: 5| and 51 are electrically connected with the common line wire 52 The wire 43connects with a retarded or: time delay relay IL, thisrelaybeingelectrically connected with the secondline wire 12, A fixed contact 13 is associated with the relay 1 I, which contact isengaged by an armature." upon energization of the relay. Thisarmature is electrically connected witha wire 15.attachedto the wire52, and the contact 13 is connected with a Wire 16 leading to a solenoid 11 which operates the proportional sludge removing valve [5. The solenoid I1 is connected with the line wire F2 by a wire 18.

Upon closing of the switch 35, the circuit is closed through the relay H from the line wire 52 to the wires 43 and 12. Upon energization of the relay, the armature I4 is attracted and brought into engagement with the fixed contact 13. This will close the circuit through the solenoid H as follows: Line wire 52, wire 15, armature 14, wire 16, solenoid 11, wire 18, and line wire 12. Energization of the solenoid 11 opens the valve l5 to release sludge from the bottom of the treating tank I. Thus the solenoid 11 is energized only upon energization of the relay H, and the valve l5 remains open for a period of time determined by the time delay action of the relay. Thus the meter operated switch 35 determines the energization intervals of the relay H, and the latter opens the valve I5 at corresponding intervals and determines the length of time that the valve remains open. Since the settled precipitate, or sludge, is deposited in the bottom of the tank I in proportion to the impurities in the raw water, the valve I5 is operated to provide frequent small quantity blow-off of sludge in proportion to the amount of raw water delivered to the water treating apparatus.

The motor I2 is electrically connected with the wire 18 and with a wire 19 connected with a fixed contact 80. This contact is associated with a second retarded or time delay relay 8| which is electrically connected with the wire 43 and with a second wire 82 connected with the line wire 12. An armature 83 associated with the relay BI is electrically connected with the wire 15. Thus current is supplied to the motor l2 when the switch unit 36 is closed for energizing the relay 8|. Upon energization of the relay 8|, current is supplied to the motor 12 as follows: Wire 15, armature 63, contact 80, wire 19, wire 16, and line wire 12. The motor operates for a period of time determined by the time delay action of the relay 8|. Accordingly, the meter operated switch 36 determines the energization intervals of the relay 81, and the latter closes the circuit to the motor 12 at corresponding intervals and determines the duration of motor operation. During each period of motor operation, the decanting tube 5 is lowered a distance proportional to the amount of raw water flowing to the treating apparatus. Thus the switch units 35 and 36 determine the frequency of energization of their respective operating circuits, and the relays II and 81 comprise electromagnetic switch means which determine; the duration of ei'rerg-i'zationv of thee respectiveoperating.circuits.

The means 27: coh'n'mlses;av small unit. whiclr may easily be. installed betweenthegear train of the meter and: its register, so that all these-parts. are incorporatedv in a single housing; structure. Both. switch. units 3.5. and: 36 and: the register are cperatively' connected? with. a. single; meter driven element or driver, namely, the spindle I1. No alteration of the meter gear train or. the register is necessary. The switch. means 2 2 is merely interposed between the' gear' train and the register, with the gears l9 and 26 connecting the meter gear train with the switch means 22 and the gears 32- and 33 connecting. theswitch means 22 with the register. The onetooth. gear 69 provides the necessary speed reduction for the switch unit 35, the closing operations of this unit occurring. at relatively long intervals as compared to the frequency of the-closing intervaiszof: the switch unit 36,

An opening 84 is provided in the casing part 24 for the passage of the wires 43, 43, and 52. Both switch units 35 and 36 are fastened to the base 26 by screws 85. Figure 7 illustrates the mannor in which the casing part 24 is clamped between the meter housing part 86 and the housing part 81 of the register 23, all the parts being detachably connected by two bolts 88, the arrangement thereof being shown in Figures 3 and 4.

The gear 68 is restrained from accidental rotation by a spring 89 which is attached to the bracket 21, which sprin yields easily to permit turning of the gear when engaged by the one tooth of the gear 69.

While the present invention is illustrated and described in association with a water treating apparatus, the invention is equally well adapted for use in other fluid circuits wherein a proportioning meter of the foregoing type is employed in a primary flow line, such as the pipe 2, for actuating switches which control operating circuits employed for operating auxiliary flow regulating devices, such as the sludge removing and chemical feeding features in the instant case, all in accordance with the rate of flow through the primary line.

It will be understood that the invention is not to be limited to the specific construction or arrangement of parts shown, but that they may be widely modified within the invention defined by the claim.

What is claimed is:

In a conventional proportioning fluid meter having a separable register for indicating the quantity flow of fluid through the meter and fluid actuated means for operating said register; an integral switch mechanism for controlling electrical circuits in accordance with the quantity flow of fluid through the meter, said switch mechanism having a housing with a base plate, two electrical switch units mounted on said plate, first, second, and third spindles, and first and second cam spindles mounted on said plate, said first spindle being driven by the fluid actuating means, said second spindle being geared to and driven by the first spindle and driving the register, said third spindle having a gear intermittently driven by an intermittenly toothed pinion on the first spindle, said first cam spindle having a first cam and being geared to and driven by the third spindle, said first cam operating the first switch, said second cam spindle having a second cam and being geared to and driven by REFERENCES CITED The following references are of record in the file of this patent:

UNITED STATES PATENTS Name Date Richards et a1. July 12, 1859 Number Number Number Name Date Bereuter Aug. 8, 1882 Marden Feb. 15, 1927 Linstow Sept. 27, 1927 Winton July 16, 1929 Bryce Sept. 29, 1931 Wallace Mar. 7, 1933 Content Aug. 28, 1934 Waugh Nov. 19, 1935 Krueger June 29, 1937 Guldner, Jr., et al. Apr. 29, 1941 Panissidi May 18, 1943 Robinson Aug. 8, 1944 Sebald et a1. Dec. 19, 1944 FOREIGN PATENTS Country Date Great Britain 1896 Great Britain Feb. 22, 1932 

